Utilizing alignment models and motion vector path blending to generate a long exposure digital image from a sequence of short exposure digital images

ABSTRACT

This disclosure relates to methods, non-transitory computer readable media, and systems that generate a virtual long exposure image from a sequence of short exposure images portraying a moving object. In various embodiments, the image transformation system aligns two digital images in the sequence of short exposure images. The image transformation system can determine a motion vector path for the moving object between the first digital image and the second digital image. The image transformation system can also blend pixels along the motion vector path to generate a blended image representative of the motion of the moving object between the first digital image and the second digital image. The image transformation system can generate additional blended images based on consecutive pairs of images in the sequence of digital images and generates a virtual long exposure image by combining the first blended image with the additional blended images.

BACKGROUND

Recent years have witnessed a significant increase in digitalphotography, particularly with the improvements and availability ofdigital cameras on mobile devices. Indeed, both hardware and softwareadvances allow for incorporation of digital cameras within a largenumber of mobile computing devices, such as tablets, smartphones, andwearable devices. For instance, conventional digital photography systemsnow allow users to capture, modify, and utilize digital photographs in avariety of different contexts.

Notwithstanding these improvements, digital photography systems stillhave a number of significant shortcomings, particularly with respect toartistic photographs. For example, mobile devices often perform poorlywhen capturing long exposure photographs. In particular, mobile devicesoften lack the physical components (e.g., lenses, advanced sensors, andadditional hardware) needed to capture clean, high-quality long exposurephotographs, such as those captured using professional-grade cameras(e.g., DSLR cameras). In addition, many parameters and settings forcapturing long exposure photographs, such as changing the ISO, shutterspeed, or aperture, are limited or unavailable on many mobile devices.

Although some conventional digital photography systems operate on mobiledevices and capture long exposure photographs, these conventionalsystems often produce inaccurate, blurry, and unsatisfactory results.Indeed, the slightest hand movement of the mobile device during a longexposure capture can distort the photograph. Thus, to achieve anacceptable long exposure photograph, an individual may have to useadditional hardware, such as a tripod and a remote trigger.Unfortunately, this additional equipment is bulky, expensive, and ofteninaccessible to individuals when photograph opportunities arise.

To overcome these issues, some conventional systems have attempted tocreate long exposure photographs on mobile devices from stillphotographs. These conventional systems require an individual to capturea sequence of images. Based on the sequence of images, these systemscreate a long exposure photograph. Even these systems, however, sufferfrom a variety of problems. For example, in many instances, theseconventional systems still require an individual to use a tripod (orother cumbersome equipment) while capturing images to obtainsatisfactory results.

Moreover, these conventional systems often generate unrealistic,inaccurate long exposure photographs. Indeed, long exposure photographsgenerated by conventional systems often include noticeable artifacts(e.g., fail to provide a smooth trail for objects in motion across thedigital images). For example, some conventional systems average framesfrom digital images captured in burst mode to generate long exposurephotographs. This approach, however, causes the long exposure photographto include unnatural pixel movements and textures (e.g., as a result oftime gap between the captured images). These quality issues are oftenexacerbated when a moving object portrayed in the long exposurephotograph is moving at high speeds.

In addition to problems with accuracy, conventional systems are alsoinflexible. For instance, in combining digital images, some conventionalsystems cannot adjust exposure settings. To illustrate, certainconventional systems cannot provide selection options for modifyinglength of long exposure capture. Similarly, many conventional systemsrequire a specific output format (e.g., JPEG), which limits flexibilityin utilizing the resulting long exposure image.

These shortcomings of conventional systems cause many photographers toutilize conventional cameras. However, in addition to the equipmentproblems discussed above, cameras have a number of problems inflexibility and functionality. For example, DSLR cameras require veryspecific conditions and lighting functions to capture particular typesof long exposure photographs. For example, in order to create a longexposure photograph with an emphasized end-frame (i.e., rear-sync flasheffect), conventional systems require the photographer to use a brightflash that can illuminate the object/scene reflected in the longexposure photograph. Accordingly, conventional systems can only generatea rear-sync flash long exposure image if the main subject is closeenough to the camera to be lit by the flash (and in a relatively darkscene). Similarly, to create a digital image with light-paintingeffects, conventional cameras require a high-contrast in brightness(e.g., between a bright light and dark surrounding environment).Accordingly, conventional systems cannot generate a light-paintingeffect in an environment with background lighting or a light source thatis not exceptionally bright.

These along with additional problems and issues exist with regard togenerating realistic long exposure photographs.

SUMMARY

Embodiments of the present disclosure provide benefits and/or solve oneor more of the foregoing or other problems in the art with systems,non-transitory computer-readable media, and methods that utilize robustalignment models and motion vector path blending to generate a longexposure image from a sequence of short exposure images. For instance,in one or more embodiments, the disclosed systems can selectively applydifferent alignment models to determine a relative alignment betweenimages in a digital image sequence. Upon aligning the digital images,the disclosed systems can utilize a continuous-motion effect techniquethat renders accurate virtual long exposure images. In particular, foreach pair of consecutive aligned frames, the disclosed systems canestimate apparent motion (e.g., a motion vector path) using a fastoptical flow technique and then blur each pixel along the optical flowdirection to create a smooth trail for moving objects.

To illustrate, in one or more embodiments, the disclosed systemsdetermine an alignment between a first digital image and a seconddigital image in a sequence of digital images portraying a movingobject. Specifically, the disclosed systems can selectively apply apixel-adjusted-gyroscope-alignment model and a feature-based-alignmentmodel to determine the alignment between the first digital image and thesecond digital image. Moreover, the disclosed systems can determine amotion vector path for the moving object based on the first digitalimage, the second digital image, and the alignment. Furthermore, in oneor more embodiments, the disclosed systems generate a first blendeddigital image by blending pixels from the first digital image utilizingthe motion vector path (e.g., averaging pixels that fall along themotion vector path). In addition, the disclosed systems can generate avirtual long exposure image portraying the moving object based on thefirst blended digital image (e.g., by combining the first blendeddigital image with other blended images).

The disclosed systems can resolve many of the shortcomings ofconventional systems discussed above. In particular, in one or moreembodiments the disclosed systems allow a user to generate ahigh-quality virtual long exposure image using a handheld mobile deviceor camera without the use of additional hardware or capabilities. Thedisclosed systems can also reduce the blurriness of long exposure photoscaptured without use of a tripod by using comprehensive alignmenttechnology to align a series of images with respect to a reference-inputimage. Additionally, the disclosed systems can improve the quality ofvirtual long exposure images by reducing the number of noticeableartifacts (e.g., by estimating and blending a set of pixels for a movingobject between frames) while allowing for flexible adjustment ofexposure and formatting. The disclosed systems can also apply specialeffects such as rear-sync flash and light-painting to virtual longexposure photographs.

The following description sets forth additional features and advantagesof one or more embodiments of the disclosed systems, computer media, andmethods. In some cases, such features and advantages will be obvious toa skilled artisan from the description or may be learned by the practiceof the disclosed embodiments.

BRIEF DESCRIPTION OF THE DRAWINGS

The detailed description provides one or more embodiments withadditional specificity and detail through the use of the accompanyingdrawings, as briefly described below.

FIG. 1 illustrates a schematic diagram of utilizing an imagetransformation system to generate long exposure images from a sequenceof short exposure digital images.

FIG. 2 illustrates a sequence-flow diagram for selecting and applying animage-alignment model from a pixel-adjusted-gyroscope-alignment modeland a feature-based-alignment model to align an input image with areference-input image in accordance with one or more embodiments.

FIGS. 3A-3F illustrate an example blended image generated using asequential pair of example short exposure digital images in accordancewith one or more embodiments.

FIG. 4 illustrates a sequence-flow diagram for generating a rear-syncflash digital image using a series of digital images in accordance withone or more embodiments.

FIG. 5 illustrates a sequence-flow diagram for generating a virtuallight-painting image from a series of blended images in accordance withone or more embodiments.

FIGS. 6A-6D illustrate an example short exposure image, an examplevirtual long exposure image, an example virtual rear-sync flash longexposure image, and an example virtual light-painting long exposureimage in accordance with one or more embodiments.

FIG. 7. Illustrates a block diagram of an environment in which an imagetransformation system can operate in accordance with one or moreembodiments.

FIG. 8 illustrates a block diagram of an exemplary computing device forimplementing one or more embodiments of the present disclosure.

FIG. 9 illustrates a flowchart of a series of acts for generating avirtual long exposure image in accordance with the one or moreembodiments.

FIG. 10 illustrates a block diagram of an exemplary computing device forimplementing one or more embodiments of the present disclosure.

DETAILED DESCRIPTION

This disclosure describes one or more embodiments of an imagetransformation system that generates a virtual long exposure image froma sequence of short exposure digital images. In particular, the imagetransformation system can detect motion of objects portrayed within thedigital images and create a smooth trail for moving pixels along themotion path. Specifically, in one or more embodiments the imagetransformation system uses comprehensive alignment technology to align astack of images or frames (e.g., from a video) that portray one or moremoving objects. Moreover, to create continuous-motion trails from thestack of aligned images, the image transformation system can use a fastoptical flow technique to estimate apparent motion between each pair ofconsecutive aligned frames. In addition, in one or more embodiments, theimage transformation system blurs each pixel along the optical flowdirection to generate a virtual long exposure image that portrays asmooth trail for moving objects. Moreover, the image transformationsystem can also blur pixels to generate virtual long exposure imageswith special effects, such as virtual rear-sync flash long exposureimages and/or virtual light-painting long exposure images.

To illustrate, the image transformation system can generate a virtuallong exposure image portraying a moving object using a sequence of shortexposure images. In one or more embodiments, the image transformationsystem aligns the sequence of short exposure images portraying a movingobject including a first digital image and a consecutive second digitalimage. The image transformation system can determine a motion vectorpath for the moving object between the first digital image and thesecond digital image. As part of determining the motion vector path forthe moving object, the image transformation system can determine thehorizontal and vertical motion of each pixel within the moving object.In some embodiments, the image transformation system identifies a set ofpixels along the motion vector path for each pixel and blends the set ofpixels to generate a blended pixel. The image transformation system canuse blended pixels to generate a virtual long exposure image (e.g., inwhich the motion path of the moving object is blurred).

As mentioned above, the image transformation system can efficiently andaccurately align the sequence of images with respect to areference-input image. For example, in one or more embodiments, theimage transformation system determines a feature-point-deficiency metricand selects an alignment model based on the feature-point deficiencymetric. In particular, the image transformation system can dynamicallyselect an image-alignment model from apixel-adjusted-gyroscope-alignment model and a feature-based-alignmentmodel based on a feature-point-deficiency metric. The imagetransformation system can use the aligned series of images to produce aclear virtual long exposure image, even for a series of short exposureimages captured without the use of a tripod.

As discussed, the image transformation system blends pixels along amotion vector path across digital images to generate a blended image. Inone or more embodiments, the image transformation system blends pixelsfor each consecutive pair of digital images in a sequence of digitalimages. In particular, for each consecutive pair of digital images, theimage transformation system can determine a motion vector path for eachpixel (e.g., each pixel of a moving object). Moreover, the imagetransformation system can identify a set of pixels from the firstdigital image along the motion vector path from the first pixel. Theimage transformation system can generate a blended pixel (e.g., ablended pixel for the first pixel) by aggregating or blending the set ofpixels along the motion vector path. In this manner, the imagetransformation system can generate blended pixels for each pixellocation in the first digital image to generate a blended image. Theblended image thus comprises blended pixels reflecting motion betweenthe first digital image and the second digital image.

The image transformation system can also utilize blended images togenerate a virtual long exposure image. For example, in one or moreembodiments, the image transformation system generates a series ofblended images that comprise blended pixels from consecutive digitalimages. The image transformation system can generate a virtual longexposure image by combining the blended images (and blended pixels). Inthis manner, the image transformation system can generate a virtual longexposure image that includes a smooth trail for moving objects portrayedwithin a sequence of digital images.

As mentioned above, the image transformation system can also generatedifferent types of long exposure images. For instance, the imagetransformation system can generate a virtual rear-sync flash longexposure image using a sequence of short exposure images. In at leastone embodiment, the image transformation system generates virtualrear-sync flash long exposure images without the requirement of slowshutter speeds and physical flashes. In particular, in one or moreembodiments, the image transformation system identifies the last digitalimage (e.g., the virtual flash frame) in a sequence of digital images.The image transformation system can modify pixels in the last digitalimage to generate a modified flash frame in which the pixels areweighted by pixel brightness (e.g., the main subject in the virtualflash frame is emphasized based on brightness). Additionally, the imagetransformation system can generate a set of modified blended images bymodifying pixels in the set of blended images based on brightness of thevirtual flash frame. In one or more embodiments, the imagetransformation combines the modified flash frame with the modifiedblended images to generate a virtual rear-sync flash long exposureimage.

The image transformation system can also generate virtual light-paintinglong exposure images. In one or more embodiments, the imagetransformation system generates a virtual light-painting long exposureimage by selecting the brightest pixel at each pixel location across theseries of blended images. The image transformation system can generatethe virtual light-painting long exposure image by using the brightestpixel at each location. For example, if in one blended image, a lightpasses through a particular pixel in any blended image, the imagetransformation system uses the brightness of the lighted pixel in thefinal virtual light-painting long exposure image. Thus, in at least oneembodiment, the image transformation system creates an image thatincludes a trail of light through all pixel locations through which thebrightest light source has passed.

The image transformation system provides many advantages and benefitsover conventional systems and methods. For example, by aligning thesequence of digital images, the image transformation system improvesaccuracy in generating long exposure photographs. Specifically, thoughconventional systems require the use of additional hardware such astripods and remote triggers, the image transformation system usescomprehensive alignment technology to align all the photos in a sequenceof digital images. Moreover, by utilizing afeature-point-deficiency-metric, the image transformation system canselect an accurate and efficient alignment model specific to thefeatures of particular digital images. In particular, the imagetransformation system can dynamically select an image-alignment modelfrom a pixel-adjusted-gyroscope-alignment model and afeature-based-alignment model based on a feature-point-deficiencymetric.

Additionally, the image transformation system improves accuracy andrealism relative to conventional systems. For example, by determiningmotion vector paths for the moving object between sequential pairs ofdigital images and blurring pixels located in the motion vector path,the image transformation system helps reduce and/or eliminate imageartifacts and inconsistencies. In particular, because the imagetransformation system can aggregate pixel values for pixels in themotion vector path, the image transformation system eliminates many gapsand artifacts present in images generated by conventional systems.

The image transformation system also improves flexibility relative toconventional systems. For example, the image transformation system canvirtually alter the exposure time by adjusting the range of blendedimages used to generate the virtual long exposure image. The imagetransformation system also provides additional flexibility by supportingJPEG and DNG output formats, which is more suitable for advanced users.Moreover, the image transformation system provides increased flexibilityby generating virtual rear-sync flash long exposure images and/orvirtual light-painting long exposure images in a variety of differentenvironments or lighting conditions (e.g., without a flash or withoutdark backgrounds).

As illustrated by the foregoing discussion, the present disclosureutilizes a variety of terms to describe features and advantages of theimage transformation system. Before describing the image transformationsystem with reference to figures below, additional detail is nowprovided regarding the meaning of such terms. For example, as usedherein, the term “image” or “digital image” refers to a digital symbol,picture, icon, or illustration. In particular, a digital image caninclude a digital graphics file that when rendered displays one or moreobjects. For instance, the term “image” can comprise a digital file thatincludes one or more subject objects and/or background scenery. Forexample, the term digital image includes digital files with thefollowing file extensions: JPG, TIFF, BMP, PNG, RAW, or PDF.

As used herein, the term “sequence of digital images” refers to a seriesof digital images (e.g., of a images of a common scene or object insequential order according to time). In particular, sequence of digitalimages refers to a series of input short exposure digital images. Forexample, the sequence of digital images can portray a moving object. Theimage transformation system can extract a sequence of digital imagesfrom a video or can directly receive the input sequence of digitalimages. Based on the sequence of short exposure digital images, theimage transformation system generates a virtual long exposure image.

As used herein, the term “motion vector path” refers to an indication ofa change in position between a first digital image and a second digitalimage. In particular, a motion vector path includes a data related tothe movement and/or direction of pixels between consecutive shortexposure digital images. For example, in a consecutive pair of digitalimages within a sequence of images, the image transformation system candetermine a motion vector path reflecting horizontal and verticalmovement of pixels portraying a moving object from a first digital imageto a second digital image. As described below, the image transformationsystem identifies pixels along the motion vector path and averages pixelvalues for those pixels to generate blended pixels. Moreover, using theblended pixels, the image transformation system can generate a blendedimage including a continuous motion trail for the moving object betweenthe first digital image and the second digital image.

As used herein, the term “blended image” refers to an image containingblended pixels. In particular, the blended image includes a blurryrepresentation of a moving object in a first digital image and thecorresponding moving object in a second digital image. The imagetransformation system can generate a blended image for each consecutivepair of digital images in a sequence of digital images. The imagetransformation system can use the generated blended images to generatevirtual long exposure images.

As used herein, the term “virtual long exposure image” refers to a longexposure image generated using a plurality of digital images (e.g., aplurality of short exposure digital images rather than a single longexposure image). In particular, the virtual long exposure imagecomprises an image generated from a plurality of digital imagesportraying a moving object, in which the moving object leaves a visibletrail. As discussed above, the image transformation system can generatevarious types of virtual long exposure images, including virtuallight-painting long exposure images, and virtual rear-sync flash longexposure images. The term “virtual light-painting long exposure image”refers to a virtual long exposure image that emphasizes moving lightobjects (thus creating an effect that the light paints a path on thedigital image). The term “virtual rear-sync flash long exposure image”refers to digital images that emphasize the subject (e.g., brightobjects) of one digital image in a sequence of digital images (e.g.,emphasizes the last digital image in a sequence). Additional detailregarding virtual long exposure images is provided below.

As used in this disclosure, the term “feature-based-alignment model”refers to an image-alignment model that aligns an input image with areference-input image based on feature points within the input image andthe reference-input image. In some embodiments, afeature-based-alignment model includes an algorithm that identifies andmatches feature points between an input image and a reference-inputimage to align the input image with the reference-input image. Forinstance, in some embodiments, the image transformation system applies afeature-based-alignment model by executing a Random Sample Consensus(“RANSAC”) algorithm, Least Median of Square (“LMedS”) regressionalgorithm, or other suitable robust-model estimation algorithms togenerate feature-alignment parameters and align an input image with areference-input image based on the feature-alignment parameters. Thisdisclosure further describes a feature-based-alignment model withreference to FIG. 2 below.

The term “feature-alignment parameters” refers to one or more factorsthat relate feature points from one digital image to correspondingfeature points from another digital image. In some embodiments, forinstance, feature-alignment parameters include factors that, whenapplied to a first digital image, align the first digital image with asecond digital image based on matching feature points between the firstand second digital images. Feature-alignment parameters may behomography-transformation parameters or affine-transformationparameters. Accordingly, in some embodiments, the image transformationsystem uses feature-alignment parameters expressed as a matrix relatingmatching feature points.

As further used in this disclosure, the term“pixel-adjusted-gyroscope-alignment model” refers to an image-alignmentmodel that aligns a digital image with another digital image based ongyroscope datasets corresponding to the digital images andpixel-to-pixel comparison between the digital images. In someembodiments, a pixel-adjusted-gyroscope-alignment model comprises animage-alignment algorithm that aligns an input image with areference-input image based on pixel-based-alignment parameters andgyroscope-alignment parameters. In some such cases, the imagetransformation system uses pixel-based-alignment parameters to adjust ormodify gyroscope-alignment parameters. This disclosure further describesa pixel-adjusted-gyroscope-alignment model with reference to FIG. 2below.

Relatedly, the term “pixel-adjusted-gyroscope-alignment parameters”refers to one or more indicators that relate an input image to areference-input image based on gyroscope data and individual-pixelcomparison between the input image and the reference-input image. Insome embodiments, for instance, pixel-adjusted-gyroscope-alignmentparameters include factors that, when applied to a first digital image,align a first digital image with a second digital image based on bothpixel-based-alignment parameters and gyroscope-alignment parameters.Further, the term “gyroscope-alignment parameters” refers to one or moreindicators that relate an input image to a reference-input image basedon gyroscope datasets. For instance, gyroscope-alignment parametersinclude transformation parameters that relate a gyroscope datasetcorresponding to one digital image to a gyroscope dataset correspondingto another digital image. In some embodiments, for instance,gyroscope-alignment parameters include a matrix that, when applied to afirst digital image, align the first digital image with a second digitalimage based on a focal length of a camera and a relative rotationbetween the input image and the reference-input image indicated bygyroscope datasets corresponding to the first and second digital images.Both pixel-adjusted-gyroscope-alignment parameters andgyroscope-alignment parameters may be homography-transformationparameters or (in some cases) affine-transformation parameters.Accordingly, in some embodiments, the image transformation system usespixel-adjusted-gyroscope-alignment parameters or gyroscope-alignmentparameters expressed as a matrix relating an input image and areference-input image.

As suggested above, in some embodiments, the image transformation systemuses a pixel-based-alignment model (instead of apixel-adjusted-gyroscope-alignment model) as an option for animage-alignment model from which to select. As used in this disclosure,the term “pixel-based-alignment model” refers to an image-alignmentmodel that aligns a digital image with another digital image based onpixel-to-pixel comparison between the digital images. In someembodiments, a pixel-based-alignment model comprises pixel-by-pixelerror analysis (e.g., sum of squared differences, sum of absolutedifferences, root mean squared intensity pixel error, normalizedcross-correlation), hierarchical motion estimation, or Fourier-basedalignment of digital images.

As used in this disclosure, the term “gyroscope dataset” refers togyroscope readings corresponding to a device utilized to capture adigital image. In some embodiments, a gyroscope dataset refers to agyroscope reading (e.g., angular momentum around each axis) captured bya gyroscope sensor or inertial measurement unit (“IMU”) at the time acamera captures a digital image. The image transformation system mayrefer to, store, or use a gyroscope dataset in a particular format. Forinstance, the image transformation system may use a gyroscope datasetstored as Euler angles (e.g., proper Euler angles or Tait-Bryan angles)and rotation data (e.g., rotational velocities) or stored asquaternions. In either case, the image transformation system may presentsuch gyroscope datasets in a gyroscope data matrix, such as a rotationmatrix for gyroscope readings.

Referring now to the figures, FIG. 1 provides an overview of utilizingan image transformation system to generate various types of virtual longexposure images from a sequence of short exposure digital images. Inparticular, FIG. 1 illustrates a series of acts 100. As shown, the imagetransformation system performs act 102 of extracting a sequence of shortexposure digital images. For example, the image transformation systemextracts three short exposure digital images (shown as “x₁,” “x₂,” and“x₃”). The series of short exposure digital images portray a movingobject. In each of the images x₁, x₂, and x₃, the moving object mayoccupy different pixel locations. In at least one embodiment, the imagetransformation system extracts the sequence of short exposure digitalimages based on a still video. In particular, the image transformationsystem can take snapshots of the still video at certain intervals oftime. Each of the snapshots represents one of the digital images in thesequence of digital images.

In alternative embodiments, the image transformation system receives asequence of short-exposure digital images. For example, the imagetransformation system can retrieve a sequence of short-exposure digitalimages from a camera that has used a burst capture mode. The burstcapture mode of a handheld mobile device or camera can be used tocapture a group of images in rapid succession (e.g., at four frames persecond or greater). Thus, the image transformation system can receive asequence of short-exposure images.

As shown in FIG. 1, the image transformation system performs an act 104of aligning the digital images. In particular, the image transformationsystem utilizes one or more alignment models to align each of the imagesx₁, x₂, and x₃. In relation to FIG. 1, the image transformation systemaligns each of the short exposure digital images with respect to areference-input image. Additional detail regarding aligning the digitalimages is provided below in connection with FIG. 2.

As shown in FIG. 1, the image transformation system performs an act 106of determining motion vector paths between consecutive digital images.As part of determining the motion vector paths between consecutivedigital images 106, the image transformation system identifiesconsecutive pairs of digital images of the sequence of short exposuredigital images. As illustrated, the image transformation systemidentifies a first pair of the consecutive digital images x₁ and x₂. Theimage transformation system also identifies a second pair of consecutivedigital images x₂ and x₃. Each consecutive pair of digital imagescomprises a first digital image and a second digital image. Asillustrated, x₁ is the first digital image of the first pair and x₂ isthe first digital image of the second pair. x₂ is the second digitalimage of the first pair while x₃ is the second digital image of thesecond pair. As illustrated, the image transformation system determinesa first motion vector path (or first set of motion vector paths) for themoving object between the first pair of the consecutive digital imagesx₁ and x₂ and a second motion vector path (or second set of motionvector paths) for the second pair of consecutive digital images x₂ andx₃.

As part of determining motion vector paths between consecutive digitalimages 106, the image transformation system determines the movement anddirection of each pixel within a moving object. In particular, the imagetransformation system identifies a horizontal and vertical motion foreach pixel within the moving object. For example, for a pair ofconsecutive images, the image transformation system identifies aparticular pixel in the moving object in the first digital image and acorresponding pixel in the second digital image. Based on the pixel inthe moving object in the first digital image and the corresponding pixelin the second digital image, the image transformation system determinesthe motion of the pixel's direction in a horizontal (i.e., x) andvertical (i.e., y) direction.

The image transformation system uses the movement and direction of eachpixel within the moving object to identify a set of pixels along themotion vector path from the pixel to the corresponding pixel. The set ofpixels along the motion vector path represent pixel values that passthrough a location along the motion vector path as the moving objectmoves from its location in the first digital image to its location inthe second digital image. The image transformation system identifies aset of pixels along a motion vector path for each pixel (e.g., eachpixel within a moving object).

As shown in FIG. 1, the image transformation system performs the act 108of generating blended images. As part of generating the blended images,the image transformation system creates a continuous motion trail byblending pixels along the motion vector path representing motion (of themoving object) between consecutive digital images. In particular, foreach pixel in the motion vector path, the image transformation systemblends the set of pixels from the first digital image along the motionvector path to generate a blended pixel. The image transformation systemgenerates a blended image by generating a blended pixel for each pixellocation. For example, the image transformation system generates a firstblended image (Bx₁x₂) depicting a continuous motion trail between themoving object in the first digital image (x₁) and the second digitalimage (x₂). Additionally, the image transformation system generates asecond blended image (Bx₂x₃) depicting a continuous motion trail betweenthe moving object in the second digital image (x₂) and the third digitalimage (x₃).

As illustrated in FIG. 1, the image transformation system uses theblended images (Bx₁x₂ and Bx₂x₃) to generate different types of longexposure images. In particular, the image transformation can combine theblended images to generate a virtual long exposure image 110, a virtualrear-sync flash long exposure image 112, and/or a virtual light-paintinglong exposure image 114. Each of these types of long exposure imageswill be described in further detail below with respect to FIGS. 3-5. Asmentioned above, the image transformation system supports both JPEG andDNG output formats for the virtual long exposure images.

As just mentioned (e.g., in relation to the act 104), in one or moreembodiments the image transformation system aligns a plurality ofdigital images to generate a virtual long exposure digital image. Inparticular, the image transformation system can select (and applies) animage-alignment model from a feature-based-alignment model or apixel-adjusted-gyroscope-alignment model.

For example, FIG. 2 illustrates the image transformation systemselecting between image-alignment models. In particular, FIG. 2 depictsa sequence-flow diagram 200 of acts 202-226 by which the imagetransformation system selects and applies an image-alignment model froma pixel-adjusted-gyroscope-alignment model and a feature-based-alignmentmodel to align an input image with a reference-input image in accordancewith one or more embodiments. As indicated by the sequence-flow diagram200, upon detecting a feature-point deficiency corresponding to afeature-based-alignment model, the image transformation system applies apixel-adjusted-gyroscope-alignment model to align an input image with areference-input image. Upon determining an absence of a feature-pointdeficiency, by contrast, the image transformation system applies apixel-based-alignment model to align an input image with areference-input image.

As shown in FIG. 2, the image transformation system performs the act 202of receiving an input image and a corresponding gyroscope dataset andthe act 204 of receiving a reference-input image and a correspondinggyroscope dataset. When receiving such an input image andreference-input image, in certain embodiments, the image transformationsystem receives an input image and a reference-image captured by acamera of a computing device (e.g., mobile device). In some cases, thecomputing device records or registers a gyroscope dataset (e.g., anindication of orientation or attitude of a camera based on angularmomentum around each axis) at the time a camera captures the input imageand an additional gyroscope dataset at the time the camera capture thereference-input image.

As further shown in FIG. 2, the image transformation system performs anact 206 of determining relative rotation based on the gyroscopedatasets. For instance, in some cases, the image transformation systemdetermines a relative rotation between the input image and thereference-input image based on (i) the gyroscope dataset correspondingto the input image and (ii) the gyroscope dataset corresponding to thereference-input image. In some such embodiments, the imagetransformation system can determine a relative rotation from thereference-input image to the input image by comparing (and determining adifference between) the gyroscope dataset corresponding to the inputimage and the gyroscope dataset corresponding to the reference-inputimage.

In addition to determining relative rotation, the image transformationsystem further performs the act 208 of identifying feature points withinthe input image and the reference-input image. In some embodiments, forinstance, the image transformation system utilizes a SIFT or SURFalgorithm to detect a set of feature points within the input image and aset of feature points within the reference-input image. Upon detection,the image transformation system can extract the respective sets offeature points within the input image and the reference-input image.

As indicated by the remaining acts 210-226, the image transformationsystem uses the identified feature points and corresponding gyroscopedatasets to either generate and apply pixel-adjusted-gyroscope-alignmentparameters or to generate and apply feature-alignment parameters. Asshown in FIG. 2, the image transformation system performs the acts 214,218, and 222 to determine (at various decision points) whether featurepoints or feature-alignment parameters corresponding to the input imageand reference-input image demonstrate a feature-point deficiency. If thefeature points or feature-alignment parameters indicate a feature-pointdeficiency, the image transformation system generates and appliespixel-adjusted-gyroscope-alignment parameters (as part of apixel-adjusted-gyroscope-alignment model). If the feature points orfeature-alignment parameters indicate an absence of a feature-pointdeficiency, the image transformation system continues acts that leadtoward generating and applying feature-alignment parameters (as part ofa feature-based-alignment model).

As shown in FIG. 2, for instance, the image transformation systemperforms the act 210 of determining a focal length of a camera. Forinstance, in some embodiments, the image transformation system estimatesa focal length of a camera that captures the input image and/or thereference-input image. When determining the focal length of a camerathat captures a set of input images, the image transformation system canupdate an estimate of the focal length based on additional input imagescaptured by the camera. Alternatively, in certain implementations, theimage transformation system queries a computing device that captures theinput image for a focal length.

In addition to determining a focal length, the image transformationsystem further performs the act 212 of generating gyroscope-alignmentparameters. As indicated by FIG. 2, in some embodiments, the imagetransformation system generates gyroscope-alignment parameters based ongyroscope datasets respectively corresponding to the input image and thereference-input image and a focal length of a camera. In some suchembodiments, the image transformation system generatesgyroscope-alignment parameters based on the relative rotation betweenthe input image and the reference-input image determined by act 206.

As further shown in FIG. 2, the image transformation system performs theact 214 of determining whether feature points within one or both of theinput image and the reference-input image include a feature-pointdeficiency. For instance, in certain embodiments, the imagetransformation system determines whether a set of feature points withinthe input image and/or a set of feature points within thereference-input image satisfy a threshold amount of feature points. Asindicated in FIG. 2, if the feature points within one or both of theinput image and the reference-input image do not satisfy the thresholdamount of feature points—and indicate a feature-point deficiency at thedecision point—the image transformation system forgoes applying afeature-based-alignment model and generatespixel-adjusted-gyroscope-alignment parameters in the act 224. If,however, the feature points within both of the input image and thereference-input image satisfy the threshold amount of feature points—andindicate an absence of a feature-point deficiency at the decisionpoint—the image transformation system continues with acts for thefeature-based-alignment model.

As indicated by FIG. 2, upon determining an absence of a feature-pointdeficiency in act 214, the image transformation system performs the act216 of matching feature points between the input image and thereference-input image. For example, in certain implementations, theimage transformation system matches feature points from a feature-pointset within the input image to features points from a feature-point setwithin the reference-input image. In some such embodiments, the imagetransformation system matches feature points between the input image andthe reference-input image according to a Brute-Force Matcher algorithm,a Fast Library for Approximate Nearest Neighbors (“FLANN”) algorithm, orany other suitable feature-point-matching algorithm.

After matching feature points, in some cases, the image transformationsystem further removes (or filters out) a subset of the matching featurepoints that conflict with the gyroscope-alignment parameters from act206. By removing such conflicting matched feature points, the imagetransformation system creates a filtered set of matching feature pointsbetween the input image and the reference-input image.

As further shown in FIG. 2, the sequence-flow diagram 200 includesanother decision point, that is the act 218. In some embodiments, theimage transformation system performs the act 218 of determining whethermatching feature points between the input image and the reference-inputimage include a feature-point deficiency. For instance, in certainimplementations, the image transformation system determines whethermatching feature points between the input image and the reference-inputimage satisfy a threshold amount of matching feature points. Asindicated in FIG. 2, if the matching feature points do not satisfy thethreshold amount of feature points—and indicate a feature-pointdeficiency at the decision point—the image transformation system forgoesapplying a feature-based-alignment model and generatespixel-adjusted-gyroscope-alignment parameters in the act 224. If,however, the matching feature points satisfy the threshold amount ofmatching feature points—and indicate an absence of a feature-pointdeficiency at the decision point—the image transformation systemcontinues with acts for the feature-based-alignment model.

Upon determining an absence of a feature-point deficiency in act 218,the image transformation system performs the act 220 of estimatingfeature-alignment parameters. For example, in some embodiments, theimage transformation system uses the matching feature points between theinput image and the reference-input image to estimate feature-alignmentparameters. As indicated above, the image transformation system canapply a RANSAC algorithm, LMedS regression algorithm, or other suitablefeature-based-image-alignment algorithm to generate thefeature-alignment parameters.

Upon determining an absence of a feature-point deficiency in act 218,the image transformation system performs the act 220 of estimatingfeature-alignment parameters. For example, in some embodiments, theimage transformation system uses the matching feature points between theinput image and the reference-input image to estimate feature-alignmentparameters. As indicated above, the image transformation system canapply a RANSAC algorithm, LMedS regression algorithm, or other suitablerobust-model algorithm to generate the feature-alignment parameters.

As further shown in FIG. 2, the sequence-flow diagram 200 includes afinal decision point, that is the act 222. In some embodiments, theimage transformation system performs the act 222 of determining whetherfeature-alignment parameters include a feature-point deficiency. Forinstance, in certain implementations, the image transformation systemdetermines whether the feature-alignment parameters would reasonablyalign the input image with the reference-input image based on (or withreference to) gyroscope datasets captured by a computing device orgyroscope-alignment parameters. For instance, the image transformationsystem can determine a differential between feature-alignment parameterscorresponding to a feature-based-alignment model and a range of expectedfeature-alignment parameters for an input image determined from arelative rotation (e.g., a range comprising maximum and minimum expectedfeature-alignment parameters for an input image based on gyroscopedatasets or gyroscope-alignment parameters).

Consistent with the decision points above, if the feature-alignmentparameters would not reasonably align the input image with thereference-input image—and indicate a feature-point deficiency—the imagetransformation system forgoes applying a feature-based-alignment modeland generates pixel-adjusted-gyroscope-alignment parameters in the act224. If, however, the feature-alignment parameters would reasonablyalign the input image with the reference-input image—and indicate anabsence of a feature-point deficiency at the decision point—the imagetransformation system continues to the act 226 of aligning the inputimage with the reference-input image (based on the feature-alignmentparameters estimated in the act 220).

As just indicated, if the image transformation system detects afeature-point deficiency while performing any of the acts 214, 218, or222, the image transformation system selects apixel-adjusted-gyroscope-alignment model instead of afeature-based-alignment model for aligning the input image with thereference-input image. In particular, upon detecting a feature-pointdeficiency in the acts 214, 218, or 222, the image transformation systemforgoes applying a feature-based-alignment model and performs the act224 of generating pixel-adjusted-gyroscope-alignment parameters.

As a precursor to generating pixel-adjusted-gyroscope-alignmentparameters, in some embodiments, the image transformation system warpsthe input image according to the gyroscope-alignment parametersgenerated in the act 212 and estimates pixel-based-alignment parametersthat would align the warped image with the reference-input image. Basedon both the pixel-based-alignment parameters and the gyroscope-alignmentparameters, in some embodiments, the image transformation systemgenerates the pixel-adjusted-gyroscope-alignment parameters.

For example, in certain implementations, the image transformation systemgenerates a down-sampled warped image based on gyroscope parameters. Theimage transformation system down-samples a reference-input image andapplies error metrics (e.g., sum of squared differences or sum ofabsolute differences, root mean squared intensity pixel error,normalized cross-correlation), hierarchical motion estimation, orFourier-based alignment to the down-sampled reference-input image andthe down-sampled warped input image. Based on such error metrics,hierarchical motion estimation, or Fourier-based alignment, thedynamic-image-alignment system estimates alignment parameters that wouldtranslate pixels from the down-sampled warped input image to thereference-input image.

As further shown in FIG. 2, the image transformation system performs theact 226 of aligning the input image with the reference-input image. Assuggested above, if the feature points or feature-alignment parametersindicate a feature-point deficiency, the image transformation systemgenerates and applies the pixel-adjusted-gyroscope-alignment parametersto the input image to align the input with the reference-input image. Ifthe feature points and the feature-alignment parameters indicate anabsence of a feature-point deficiency, the image transformation systemgenerates and applies feature-alignment parameters to the input image toalign the input with the reference-input image.

As described above, FIG. 2 demonstrates a flexible and selectiveimage-alignment algorithm. In contrast to some conventionalimage-alignment systems, the disclosed image transformation system inFIG. 2 uses a flexible approach that selects between apixel-adjusted-gyroscope-alignment model and a feature-based-alignmentmodel to align digital images. Alternatively, in some embodiments, theimage transformation system employs a different selectiveimage-alignment algorithm—by using a feature-point-deficiency metric toselect between a pixel-based-alignment model and afeature-based-alignment model to align digital images. Accordingly,based on identifying a feature-point deficiency, in some cases, theimage transformation system optionally applies a pixel-based-alignmentmodel (instead of a feature-based-alignment model) to align an inputimage with a reference-input image. In such embodiments, the imagetransformation system applies the pixel-based-alignment model bycomparing pixels across an input image and a reference-input image anddetermining pixel-based-alignment parameters for aligning the inputimage with the reference-input image based on overlapping pixels betweenthe images. Additional detail regarding aligning digital images isdescribed in Aligning Digital Images By Selectively ApplyingPixel-Adjusted-Gyroscope Alignment And Feature-Based Alignment Models,application Ser. No._, which is incorporated by reference herein in itsentirety.

As discussed above, upon aligning digital images, the imagetransformation system can generate a blended image. For example, FIGS.3A-3F illustrate generating a blended image using a consecutive pair ofshort exposure digital images in accordance with one or moreembodiments. In particular, FIG. 3A illustrates an example first digitalimage and an example second digital image. FIG. 3B illustratesdetermining a motion vector path for pixels between the first digitalimage and the second digital image (e.g., determining a motion vectorpath for a moving object). FIG. 3C shows the image transformation systemidentifying a set of pixels along the motion vector path from a firstpixel in the first digital image to generate a blended pixel. Moreover,FIG. 3D illustrates an example blended image based on the first digitalimage and the second digital image and FIG. 3E illustrates combining aplurality of blended images to generate a virtual long exposure digitalimage. Furthermore, FIG. 3F illustrates an approach to generatingblended images that utilizes intermediate images/pixels between a firstdigital image and a second digital image.

As just mentioned, FIG. 3A illustrates a first digital image 302 and asecond digital image 304. As illustrated, the first digital image 302and the second digital image 304 are consecutive digital images in asequence of images portraying a moving object 305. In particular, thefirst digital image 302 portrays the moving object 305 in a firstposition 306 a and the second digital image portrays the moving object305 in a second position 306 b. The moving object 305 in the firstposition 306 a includes a first pixel 308, and the moving object 305 inthe second position 306 b includes a corresponding pixel 310.

As illustrated in FIG. 3A, the first digital image 302 and the seconddigital image 304 are both short exposure input images that belong in asequence of images. The first digital image 302 and the second digitalimage 304 can be frames from a video or individual images taken using acamera burst mode. Furthermore, the first digital image 302 and thesecond digital image 304 illustrated in FIG. 3A can represent any twoconsecutive pairs of digital images in a sequence of digital images.

FIG. 3B illustrates the first digital image 302 with the second position306 b of the moving object 305 from the second digital image 304superimposed over the first digital image 302 (for ease in showing therelative position of moving object 305 between digital images within acommon reference alignment). As shown in FIG. 3B, the imagetransformation system determines a motion vector path 314 from the firstpixel 308 of the first digital image 302 to the corresponding pixel 310of the second digital image 304. As part of determining the motionvector path 314 for the moving object 306, the image transformationsystem determines a horizontal motion and vertical motion of the firstpixel 308. The image transformation system utilizes optical flowdetection technology in order to identify the horizontal motion and thevertical component from the first pixel 308 to the corresponding pixel310. For example, in one embodiment, the image transformation systemuses an optical flow technique to identify the horizontal and verticalcomponents of the motion vector path 314. Equation 1 represents anoptical flow technique by which the image transformation systemdetermines the motion vector path 314 comprising motion in thehorizontal direction (F_(i,x)) and the vertical direction (F_(i,y)).

I _(i) ^((a))(x,y)=I _(i+1) ^((a))(x+F _(i,x)(x,y),y+F _(i,y)(x,y))  (1)

In at least one embodiment, the image transformation system uses any oneof a variety of flow detection techniques to determine the motion vectorpath 314. Additionally, the image transformation system is not limitedto applying flow detection to full resolution digital images. The imagetransformation system can down-sample a digital image and apply the flowdetection to the down-sampled digital image, thus efficiently utilizingcomputing resources when determining the motion vector path.

In Equation 1, I_(i) represents the first digital image 302, and I_(i+1)represents the second digital image 304. More particularly, I_(i)^((a))(x, y) represents the location of the first pixel 308 (or group ofpixels) in the first digital image 302 and I_(i+1) ^((a))(x, y)represents the location of the corresponding pixel 310 (or group ofpixels) in the second digital image 304. In this manner, the imagetransformation can determine the motion vector path 314. Moreover, bydetermining the horizontal motion F_(i,x) and the vertical motionF_(i,y) of each pixel (or group of pixels) in the moving object, theimage transformation system can determine one or more motion vectorpaths for pixels of the moving object 305.

As mentioned, the image transformation system can utilize a variety ofoptical flow techniques to determine a motion vector path (e.g., amotion field) for moving objects between digital images. For example,the image transformation system can utilize the optical flow techniquesdescribed by J. L. Barron, D. J. Fleet, S. S. Beauchemin, and T. A.Burkitt in Performance of Optical Flow Techniques, International Journalof Computer Vision, Vol. 12, Issue 1, 45-77 (1994).

By determining motion vector paths, the image transformation system candetermine sets of pixels along a motion vector path for each pixel inthe moving object 306. For example, FIG. 3C illustrates determining aset of pixels along a motion vector path in accordance with one or moreembodiments. In particular, FIG. 3C illustrates a second pixel 320 inthe first digital image 302 (at the second location 306 b). As shown,the image transformation system utilizes the vector motion path 314 todetermine a set of pixels 322 along the motion vector path 314 from thefirst pixel 308 to the second pixel 320. Notably, in the embodiment ofFIGS. 3A-3D, the second pixel 320 is in the same position within thefirst digital image 302 as the corresponding pixel 310 illustrated inFIG. 3B.

As shown in FIG. 3C, the image transformation system utilizes the set ofpixels 322 to generate a blended pixel 326 corresponding to the secondpixel 320. Specifically, the image transformation system can generatethe blended pixel 326 for a blended image 324 by blending (e.g.,combining or averaging) the pixel values from the set of pixels 322.Notably, the blended pixel 326 is in the same relative position withinthe blended image 324 as the second pixel 320 within the first digitalimage 302 (i.e., in the second position 306 b).

Though FIG. 3C illustrates generating the blended pixel 326 from thespecific set of pixels 322 along the motion vector path 314 between thefirst pixel 308 and the second pixel 320, the image transformationsystem can generate blended pixels from motion vector paths for each ofthe pixels in the first digital image (e.g., each of the pixels that themoving object moves through). Accordingly, the image transformationsystem can determine a motion vector path and a set of pixels for eachpixel located within a moving object boundary defined by motion of themoving object 305 between the first digital image 302 and the seconddigital image 304. Moreover, for each pixel (e.g., each pixel within amotion boundary), the image transformation system can combine a set ofpixels along a corresponding motion vector path to generate blendedpixels for a blended image.

For example, FIG. 3D illustrates the blended image 324 with blendedpixels corresponding to each pixel within the first digital image 302(e.g., blended pixels for each pixel within a motion boundary).Specifically, FIG. 3D illustrates the blended image 324 including theblended moving object 328 representing the movement of the moving object305 between the first digital image 302 and the second digital image304. As just described, the image transformation system generates theblended image 324 by aggregating the set of pixels along a motion vectorpath for each pixel within the first digital image 302.

The blended image 324 of FIG. 3D is for illustrative purposes and doesnot necessarily reflect an actual blended image. In particular, actualblended pixels of the blended moving object 328 vary by intensitydepending on the intensity of the corresponding sets of pixels. Thus, inat least one embodiment, the shape of the blended moving object 328 willbe irregular and include pixels of varying intensity.

In at least one embodiment, the image transformation system generatesblended pixels based on aggregated pixel values solely from the movingobject 305. In particular, the image transformation system distinguishesbetween background and the moving object 305. The image transformationsystem aggregates sets of pixel values associated with the moving object305 and generates blended pixels along the motion vector path 314 basedon those values (without blending background pixels not associated withthe moving object 305). In other embodiments, the image transformationsystem generates blended pixel values for all pixels in a digital image.

As mentioned above, the image transformation system can also generate avirtual long exposure image by combining blended images. Indeed,although FIGS. 3A-3D illustrate generation of the blended image 324based on the first digital image 302 and the second digital image 304,the image transformation system can generate a blended image for eachconsecutive pair of digital images in a sequence of images. Moreover,the image transformation system can combine the blended images togenerate a virtual long exposure image.

For example, FIG. 3E illustrates generating a virtual long exposureimage by combining blended images. Specifically, FIG. 3E illustrates theimage transformation system generating a plurality of blended images324-324 n from consecutive digital images in a sequence of digitalimages. As shown, each blended image illustrates motion of a movingobject between digital images in the sequence of digital images.Moreover, FIG. 3E illustrates the image transformation system combiningthe plurality of blended images 324-324 n to generate a virtual longexposure digital image 330. Specifically, the image transition systemcan combine (e.g., average) the pixel values of the blended images324-324 n to generate the pixel values for the virtual long exposuredigital image 330.

For example, Equation 2 below provides an example function forgenerating a virtual long exposure image L.

$\begin{matrix}{L = {\frac{1}{N - 1}{\sum\limits_{i = 1}^{N - 1}B_{i}}}} & (2)\end{matrix}$

In equation 2, N represents the number of digital images in the sequenceof digital images. B_(i) represents an image in the set of blendedimages B={B_(i); i∈{1, . . . , N−1}}.

Although FIGS. 3A-3E illustrate a specific approach to generating avirtual long exposure image, it will be appreciated that the imagetransformation system can utilize alternative approaches. For example,although FIG. 3C shows a particular illustration for averaging a set ofpixels identified by a motion vector path to generate a blended image,the image transformation system can generate a blended image utilizing avariety of approaches. For example, the image transformation system cangenerate blended pixels by simulating the motion of the moving objectfrom the moving object in the first position 306 a to the moving objectin the second position 306 b by generating and blending intermediateimages.

For example, FIG. 3F illustrates generating intermediate images based ona vector motion path. As shown, the image transformation systemgenerates intermediate images 340 of the moving object 305 from thefirst digital image 302 along the vector motion path 314 between thefirst position 306 a and the second position 306 b. Specifically, theimage transformation system generates intermediate samples of each pixelof the moving object in the first position 306 a to the second position306 b along the vector motion path 314.

Moreover, as shown in FIG. 3F, the image transformation system combinesthe intermediate images 340 to generate a blended image 324 including ablended moving object 326. Notably, by combining each of theintermediate images 340, the image transformation system, for eachpixel, combines a set of pixels along the vector motion path 314. Thus,the embodiment illustrated in FIG. 3F is a specific approach to theembodiment described in FIG. 3C.

In at least one embodiment, the image transformation system varies thenumber of intermediate pixel samples utilized to generate the blendedimage 324. For example, for longer motion vector paths 314representative of a faster-moving object, the image transformationsystem can increase (or decrease) the number of intermediate pixelsamples. Likewise, for shorter motion vector paths 314, the imagetransformation system can limit (or increase) the number of intermediatepixel samples. In at least one embodiment, the number of intermediatepixel samples is fixed.

In at least one embodiment, the image transformation system adjustsexposure settings by identifying particular ranges for the set ofblended images to combine to generate a virtual long exposure image. Forexample, to simulate shorter exposure times, the image transformationsystem reduces the number of blended images used to generate the virtuallong exposure images. The image transformation system can automaticallyidentify the blended images to use in generating a virtual long exposureimage. In at least one embodiment, the image transformation systemreceives user input indicating the range of blended images to include inthe virtual long exposure image.

As mentioned previously, the image transformation system can generatevarious types of virtual long exposure images. In addition to generatingregular virtual long exposure images as described above, the imagetransformation system can generate rear-sync flash long exposure digitalimages, and virtual light-painting long exposure digital images. FIG. 4illustrates the image transformation system generating a rear-sync flashlong exposure digital image. FIG. 5 illustrates the image transformationsystem generating a virtual light-painting long exposure digital image.

Specifically, FIG. 4 illustrates a sequence-flow diagram of a series ofacts 400 performed by the image transformation system to generate avirtual rear-sync flash long exposure digital image. As shown in FIG. 4,the series of acts 400 includes an act 402 of identifying a last digitalimage in a sequence of digital images. In other words, the imagetransformation system selects a last digital image 412 from a sequenceof digital image 410 corresponding with the desired moment of a virtualflash (e.g., a frame to be emphasized in the resulting long exposuredigital image). As illustrated in FIG. 4, the image transformationsystem identifies the last digital image 412 as a virtual flash frame.

Although in FIG. 4, the image transformation system identifies the lastdigital image 412 as the virtual flash frame, the image transformationsystem can identify other images, beside the last digital image, fromthe series of images as the virtual flash frame. For example, the imagetransformation system can select an image from the middle of thesequence of images to clarify the main subject in the middle of a motiontrail. Alternatively, the image transformation system can identify thefirst image in a series of images as the virtual flash frame. In atleast one embodiment, the image transformation system identifies thevirtual flash frame based on user input.

As illustrated in FIG. 4, the image transformation system also performsan act 404 of emphasizing pixels in the last digital image 412 based onthe brightness of the last digital image 412. In particular, the imagetransformation system weights the contribution of each pixel from thelast digital image with the brightness of the pixel to generate amodified flash frame 416 using a shock frame. In particular, the imagetransformation system weights pixels in the modified flash frame 416according to the brightness of each pixel in the image.

For example, the image transformation system generates the modifiedflash frame 416 from the final digital image 412 in the sequence ofdigital images 410 by multiplying each pixel by a brightness value ofcorresponding pixels in the final digital image 412. Thus, brighterobjects/pixels from the last digital image 412 are emphasized in themodified flash frame 416 because they are weighted by brightness basedon a shock frame. For example, in some embodiments, the imagetransformation system applies a shock frame comprising a grayscaleversion of the final digital image 412 normalized to the range of [0,1]to the final digital image 412 to generate the modified flash frame 416.For example, as illustrated in the act 406 of FIG. 4, the imagetransformation system emphasizes the ball (i.e., the brightest pixels)in the last digital image to generate the modified flash frame 416.

As illustrated in FIG. 4, the series of acts 400 includes an act 404 ofmodifying blended images based on the brightness of the last digitalimage. In particular, the image transformation system generates modifiedblended images 415 a-415 n from a set of blended images 414 a-414 nbased on the brightness of the last digital image 412.

As discussed previously (e.g., in relation to FIGS. 3A-3F), the imagetransformation system can generate blended images that reflect movementbetween consecutive digital images in a digital image sequence. Inrelation to FIG. 4, the image transformation system generates the set ofblended images 414 a-414 n in this manner. The image transformationsystem then modifies the plurality of blended images 414 a-414 n basedon the brightness of the last digital image 412.

In particular, the image transformation system modifies the set ofblended images 414 a-414 n by emphasizing pixels based on the inverse ofthe shock image or the brightness of the last digital image 412. Forexample, as illustrated in the act 404 of FIG. 4, the imagetransformation system emphasizes pixels located around, but notincluding, the brightest pixels in the last digital image 412. In otherwords, the image transformation system de-emphasis pixels in the set ofblended images 414 a-414 n that are in the same position of brightpixels in the last digital image 412. To illustrate, the imagetransformation system can generate modified blended images by applyingthe inverse of a grayscale version of the final digital image 412normalized to the range of [0,1] to the set of blended images 414 a-414n.

As shown in FIG. 4, the series of acts 400 also includes an act 408 ofcombining the modified last digital image 416 with the modified blendedimages 415 a-415 n to generate a virtual rear-sync flash digital image418. The virtual rear-sync flash digital image includes a motion trailas well as a clear main subject. By modifying the blended images andemphasizing pixels in the last digital image based on the brightness ofpixels in the last digital image, the image transformation system helpsovercome shortcomings of conventional systems. For instance, the imagetransformation system can generate a virtual rear-sync flash digitalimage using short exposure images captured in daylight conditions andfor moving objects far away from the camera.

Equation 3 below provides an example function for generating a rear-syncflash digital image LR.

$\begin{matrix}{{LR} = {{\frac{1}{N - 1}\left( {1 - \overset{\_}{I_{N}}} \right){\sum\limits_{i = 1}^{N - 1}B_{i}}} + {\overset{\_}{I_{N}}I_{N}^{(a)}}}} & (3)\end{matrix}$

In equation 3, N represents number of digital images in the sequence ofdigital images, and B_(i) represents an image in the set of blendedimages B={B_(i); i∈{1, . . . , N−1}}. I_(N) represents the shock framereflecting the brightness of the last digital image I_(N) ^((a))normalized to the range of [0,1]. {circle around (*)} is the pixel-wisemultiplication. In at least one embodiment, I_(N) comprises a grayscaleversion of the last digital image.

As mentioned above, the image transformation system can also generatevirtual light-painting long exposure images. FIG. 5 illustrates asequence-flow diagram of a series of acts 500 performed by the imagetransformation system to generate a virtual light-painting long exposureimage. As shown in FIG. 5, the series of acts 500 includes an act 502 ofgenerating a series of blended images. As discussed above (e.g., inrelation to FIGS. 3A-3F) the image transformations system can generate aplurality of blended images from a sequence of digital images. Forexample, as illustrated in FIG. 5, the image transformation systemgenerates a set of blended images 508 a-508 n from a sequence of digitalimages portraying a light source 514 moving. As illustrated in FIG. 5,the set of blended images 508 a-508 n depicts motion of the light source514 from the left side of the digital images to the right side of thedigital images. For illustrative purposes, two pixel locations,including a central pixel location 510 and a corner pixel location 512,have been highlighted in the set of blended images 508 a-508 n.Specifically, the set of blended images 508 a-508 n include centralpixels 516 a-516 n at the central pixel location 510 and corner pixels518 a-518 n at the corner pixel location 512

As shown in FIG. 5, the series of acts 500 includes an act 504 ofidentifying a brightest pixel at each pixel location. As part of the act504, the image transformation system extracts a brightness value foreach pixel location across the set of blended images 508 a-508 n. Forexample, in relation to FIG. 5, the image transformation system comparesthe central pixels 516 a-516 n at the central location 510 anddetermines that the second blended image 508 b includes the brightestpixel for the central pixel location 510. Indeed, in the second blendedimage 508 b, the motion trail for the light source 514 passes throughthe central pixel location 510.

The image transformation system also compares the corner pixels 518a-518 n at the corner location 512. However, the light source 514 doesnot pass through the corner pixel location 512 in any of the blendedimages 508. Therefore, the brightest pixel for the corner pixel location512 is darker compared to the brightest pixel for the central pixellocation 510. In at least one embodiment, the image transformationsystem selects the brightest pixel at each pixel location for a seriesof grayscale blended images.

As illustrated in FIG. 5, the series of acts 500 also includes act 506of using the brightest pixels at each pixel location to generate avirtual light-painting long exposure image 520. In particular, the imagetransformation system iterates through each pixel location, identifiesthe brightest pixel at the pixel location, and adds the brightest pixelto the virtual light-painting long exposure image 520. As shown, in thismanner the image transformation system creates a strong light motiontrail across each pixel location through which the light source 514passes. Additionally, because the image transformation system identifiesthe brightest pixels at each location, the image transformation systemcan maximize the contrast between bright pixels and dark pixels invirtual light-painting images even when using a sequence of shortexposure images with low-intensity light sources relative to the scene.

Equation 4 below provides an example function for generating a virtuallight-painting long exposure image at each pixel location L(x,y).

L(x,y)=B _(i)(x,y);i=arg max₁ ^(N-1) B _(i) (x,y)  (4)

In equation 4, B_(i) represents an image in the set of blended imagesB={B_(i); i∈{1, . . . , N−1}}. arg max is pixel-wise operator selectingthe image with the brightest pixel, and B_(i) is a version the blendedimages that represent the brightness of B_(i). In at least oneembodiment, B_(i) is the grayscale version of B_(i).

FIGS. 3A-5 illustrate generating different types of virtual longexposure images using a sequence of short exposure images. FIGS. 6A-6Dillustrate example images representing the different types of virtuallong exposure images. In particular, FIG. 6A illustrates an exampleshort exposure input image. Indeed, FIG. 6A illustrates a digital imageof a river with rough water flowing through rocks. Because the digitalimage of FIG. 6A is a short exposure image, the moving water appearsrough and turbulent as it runs through the rocks portrayed in the image.

FIG. 6B illustrates an example virtual long exposure image based on thedigital image of FIG. 6A. In contrast to the short exposure image ofFIG. 6A, the virtual long exposure image of FIG. 6B is smoothed andflowing. Indeed, the image transformation system utilizes motion vectorpaths to blend pixels across a sequence of digital images to generate asmooth portrayal of water in the river. The image transformation systemgenerates the virtual long exposure image of FIG. 6B without the needfor a tripod, camera with a long shutter flash, or other equipment.

FIG. 6C illustrates an example virtual rear-sync flash long exposuredigital image. As illustrated in FIG. 6C, the image transformationsystem analyzes a sequence of digital images that include a moving car.The image transformation system aligns and blends the sequence ofdigital images to generate a rear-sync flash long exposure digital imagethat portrays the car with a clear, smooth trail (without artifacts)along the motion path of the car. Notably, the image transformationsystem generates the rear-sync flash long exposure digital image of thecar, even though the car is a far distance from the camera and a cameraflash cannot clearly illuminate the car. As discussed above,conventional long exposure cameras would not produce such a result.

Finally, FIG. 6D illustrates an example virtual light-painting longexposure digital image. In particular, the image transformation systemgenerates the virtual light-painting long exposure digital image from asequence of digital images portraying a woman moving a light in theshape of a heart. Notably, the background of FIG. 6D is not uniformlydark. Indeed, the background includes a variety of light objects (e.g.,windows, hall lights, etc.). Nonetheless, the virtual light-paintinglong exposure digital image clearly portrays the path of movement of thelight. As discussed above, conventional long exposure systems would notproduce such a result.

FIG. 7 illustrates a schematic diagram of an environment 700 in whichthe image transformation system 706 may be implemented in accordancewith one or more embodiments. As shown in FIG. 7, the environment 700includes various computing devices including server device(s) 702 andone or more client devices 708 a, 708 b. In addition, the environment700 includes a network 706. The network 706 may be any suitable networkover which the computing devices can communicate. Example networks arediscussed in more detail below with regard to FIG. 10.

As shown, the environment 700 includes the client devices 708 a, 708 b.The client devices 708 a, 708 b may comprise various types of clientdevices. For example, in some embodiments, the client devices 708 a, 708b include a mobile device, such as a laptop, a tablet, a mobiletelephone, a smartphone, etc. In other embodiments, the client devices708 a, 708 b include a non-mobile device, such as a desktop or server,or another type of client device. Additional details with regard to theclient devices 708 a, 708 b are discussed below with respect to FIG. 10.

As illustrated in FIG. 7, the environment 700 includes the serverdevice(s) 702. The server device(s) 702 can generate, store, receive,and/or transmit any type of data, including digital images and virtuallong exposure digital images. For example, the server device(s) 702 canreceive, store, and modify a sequence of digital images from the clientdevice 708 a and transmit virtual long exposure digital image to theclient device 708 a. In one or more embodiments, the server device(s)702 comprises a data server. The server device(s) 702 can also comprisea communication server or a web-hosting server. Additional detailregarding the server device(s) 702 are provided below in relation toFIG. 10.

As shown, the server device(s) 702 includes the image editing system 704and the image transformation system 706. The image editing system 704,in general, facilitates the creation, modifying, editing, sharing,and/or management of digital images. For example, the image editingsystem 704 can store a repository of digital images and (in response torequests from the client devices 708 a-708 b) modify the digital images(e.g., perform a variety of photo-editing functions).

As shown, the image editing system 704 can include the imagetransformation system 706. For example, as described above, the imagetransformation system 706 can generate a virtual long exposure imagefrom a sequence of short exposure images (e.g., images captured orreceived form the client device 708 a). Moreover, the imagetransformation system 706 (via the image editing system 704) can providethe virtual long exposure image to the client device 708 a.

As illustrated, in one or more embodiments, the server device(s) 702 caninclude all, or a portion of, the image transformation system 706. Inparticular, the image transformation system 706 can comprise anapplication running on the server device(s) 702 or a portion of asoftware application that can be downloaded from the server device(s)702. For example, the image transformation system 706 can include a webhosting application that allows a client device 708 a to interact withcontent hosted on the server device(s) 702. To illustrate, in one ormore embodiments of the environment 700, the client device 708 aaccesses a web page supported by the server device(s) 702. Inparticular, the client device 708 a can run an application to allow auser to access, generate view, select, create, and/or modify virtuallong exposure images within a web page or website hosted at the serverdevice(s) 702 (e.g., a web page enables a user to provide a shortexposure target image, and receive, from the server, a virtual longexposure image).

Although FIG. 7 illustrates a particular arrangement of the serverdevice(s) 702, the client devices 708 a, 708 b and the network 706,various additional arrangements are possible. For example, while FIG. 7illustrates the one or more client devices 708 a, 708 b communicatingwith the server device(s) 702 via the network 706, in one or moreembodiments a single client device may communicate directly with theserver device(s) 702, bypassing the network 706.

Similarly, although the environment 700 of FIG. 7 is depicted as havingvarious components, the environment 700 may have additional oralternative components. For example, the image transformation system 706can be implemented on multiple computing devices. In particular, theimage transformation system 706 may be implemented in whole by theserver device(s) 702 or the image transformation system 706 may beimplemented in whole by the client device 708 a (e.g., the client device708 a can capture digital images, store digital images, and/or generatevirtual long exposure digital images utilizing the image transformationsystem 706). Alternatively, the image transformation system 706 may beimplemented across multiple devices or components.

Referring now to FIG. 8, additional detail is provided regardingcapabilities and components of the image transformation system 706 inaccordance with one or more embodiments. In particular, FIG. 8 shows aschematic diagram of an example architecture of the image transformationsystem 706 of an image editing system 704 and implemented on a computingdevice 800 (e.g., the client device(s) 708 a-708 b and/or the serverdevice(s) 702). The image transformation system 706 can represent one ormore embodiments of the image transformation system describedpreviously.

As illustrated in FIG. 8, the image transformation system 706 includesvarious components for performing the processes and features describedherein. For example, the image transformation system 706 includes animage extractor 802, an image aligner 804, a motion vector pathextractor 806, a blended image generator 808, a virtual long exposureimage generator 810, a virtual rear-sync flash long exposure imagegenerator 812, a virtual light-painting image generator 814, and animage database 816. Each of these components is described below in turn.

As mentioned above, the image transformation system 706 includes theimage extractor 802. In general, the image extractor 802 facilitatesidentifying, accessing, receiving, obtaining, generating, and importingimages. In one or more embodiments, the image extractor 802 operates inconnection with the image editing system 704 to access images. Inparticular, the image extractor 802 can extract short exposure images818 from video files. Further, as shown, the image extractor 802 canaccess one or more of the images within the image database 816.

As shown, the image transformation system 706 includes the image aligner804. The image aligner 804 can generate a relative alignment betweenmultiple digital images (e.g., align the digital images to a commonreference). As described above, the image aligner 804 uses featurepoints and corresponding gyroscope datasets to either generate and applypixel-adjusted-gyroscope-alignment parameters or to generate and applyfeature-alignment parameters to align a series of images. The imagealigner 804 selects and applies one of the feature-based-alignment modelor a pixel-adjusted-gyroscope-alignment model.

As illustrated in FIG. 8, the image transformation system 706 includesthe motion vector path extractor 806. As described above, the motionvector path extractor 806 determines a motion vector path for pixels,feature-points, and/or moving objects between a first digital image anda second digital image from a consecutive pair of digital images. Moreparticularly, the motion vector path extractor 806 determines ahorizontal motion and a vertical motion for each pixel in the movingobject. Using the motion vector of each pixel within the moving object,the motion vector path extractor 806 determines the motion vector path.

The image transformation system 706 includes the blended image generator808. As described above, the blended image generator 808 generatesblended pixels along the motion vector path by aggregating pixel valuesfrom a set of pixels along the motion vector path. The blended imagegenerator 808 generates a blended image for each consecutive pair ofdigital images in a sequence of digital images. The blended imagegenerator 808 can send blended images to the virtual long exposure imagegenerator 810, the virtual rear-sync flash long exposure image generator812, and/or the virtual light-painting image generator 814.

The image transformation system 706 includes the virtual long exposureimage generator 810. The virtual long exposure image generator 810 cancreate, generate, produce, and/or provide a virtual long exposure image.As described above, the virtual long exposure image generator 810combines and averages the set of blended images to generate a regularvirtual long exposure image. In particular, the virtual long exposureimage portrays a motion trail of a moving object.

The image transformation system 706 includes the virtual rear-sync flashlong exposure image generator 812 (i.e., as part of the virtuallong-exposure image generator 810). The virtual rear-sync flash longexposure image generator 812 can create, generate, produce, and/orprovide a virtual rear-sync flash long exposure image. As describedabove, the virtual rear-sync flash long exposure image generator 812extracts the brightness of pixels in the last digital image. The virtualrear-sync flash long exposure image generator 812 modifies the set ofblended images and the last digital image based on the extractedbrightness of the last digital image and combines the modified images togenerate a virtual rear-sync flash long exposure image. Moreparticularly, the virtual rear-sync flash long exposure image generator812 generates an image including both a motion trail and a clear mainsubject from the last digital image.

The image transformation system 706 also includes virtual light-paintingimage generator 814 (e.g., as part of the virtual light-painting imagegenerator 814). The virtual light-painting image generator 814 cancreate, generate, produce, and/or provide a virtual light-painting longexposure image. As described above, the virtual light-painting imagegenerator 814 identifies the brightest pixel at each pixel location in aseries of blended images. The virtual light-painting image generator 814then generates a virtual light-painting image using the brightest pixelsat each location.

As also shown, the image transformation system 706 includes the imagedatabase 816. The image database 816 includes the short exposure images818. The short exposure images 818 can include a sequence of shortexposure images portraying a moving object. The short exposure images818 can be captured using burst mode. Additionally, short exposureimages can be extracted from video footage.

The image database 816 also includes blended images 820. The blendedimages 820 include blended images generated by the blended imagegenerator 808. More particularly, the blended images 820 include imagesportraying motion of moving objects between consecutive pairs of digitalimages in a sequence of digital images.

In addition, as shown, the image database 816 includes long exposureimages 822. The long exposure images 822 can include long exposureimages generated by the image transformation system 904. In particular,long exposure images 822 can include images generated by the virtuallong exposure image generator 810, the virtual rear-sync flash longexposure image generator 812, and/or the virtual light paining imagegenerator 814.

Each of the components 802-822 of the image transformation system 706can include software, hardware, or both. For example, the components802-822 can include one or more instructions stored on acomputer-readable storage medium and executable by processors of one ormore computing devices, such as a client device (e.g., a mobile clientdevice) or server device. When executed by the one or more processors,the computer-executable instructions of the image transformation system706 can cause a computing device to perform the long exposure imagegeneration methods described herein. Alternatively, the components802-822 can include hardware, such as a special-purpose processingdevice to perform a certain function or group of functions. In addition,the components 802-822 of the image transformation system 706 caninclude a combination of computer-executable instructions and hardware.

Furthermore, the components 802-822 of the image transformation system706 may be implemented as one or more operating systems, as one or morestand-alone applications, as one or more modules of an application, asone or more plug-ins, as one or more library functions or functions thatmay be called by other applications, and/or as a cloud-computing model.Thus, the components 802-822 may be implemented as a stand-aloneapplication, such as a desktop or mobile application. Additionally, thecomponents 802-822 may be implemented as one or more web-basedapplications hosted on a remote server. The components 802-822 may alsobe implemented in a suite of mobile device applications or “apps.” Toillustrate, the components 902-930 may be implemented in an application,including but not limited to ADOBE® INDESIGN®, ADOBE ACROBAT®, ADOBE®ILLUSTRATOR®, ADOBE PHOTOSHOP®, ADOBE® CREATIVE CLOUD® software.“ADOBE,” “INDESIGN” “ACROBAT,” “ILLUSTRATOR,” “PHOTOSHOP,” and “CREATIVECLOUD” are either registered trademarks or trademarks of Adobe SystemsIncorporated in the United States and/or other countries.

FIGS. 1-8, the corresponding text, and the examples provide a number ofdifferent methods, systems, devices, and non-transitorycomputer-readable media of the image transformation system 706. Inaddition to the foregoing, one or more embodiments can also be describedin terms of flowcharts comprising acts for accomplishing a particularresult, such as the flowcharts of acts shown in FIG. 9. Additionally,the acts described herein may be repeated or performed in parallel withone another or parallel with different instances of the same or similaracts.

As mentioned, FIG. 9 illustrates a flowchart of a series of acts 900 forgenerating a virtual long exposure image using a sequence of shortexposure images. While FIG. 9 illustrates acts according to oneembodiment, alternative embodiments may omit, add to, reorder, and/ormodify any of the acts shown in FIG. 9. The acts of FIG. 9 can beperformed as part of a method. Alternatively, a non-transitorycomputer-readable medium can comprise instructions that, when executedby one or more processors, cause a computing device to perform the actsof FIG. 9. In some embodiments, a system can perform the acts of FIG. 9.

In one or more embodiments, the series of acts 900 is implemented on oneor more computing devices, such as the computing device 800 or theclient device 708 a. In addition, in some embodiments, the series ofacts 900 is implemented in a digital environment for creating or editingdigital content (e.g., images).

The series of acts 900 includes an act 910 of determining alignmentbetween a first image and a second image. In particular, the act 910 caninvolve determining an alignment between a first digital image and asecond digital image in a sequence of digital images portraying a movingobject. Specifically, the act 910 can include based on afeature-point-deficiency metric, selecting an image-alignment model froma pixel-adjusted-gyroscope-alignment model and a feature-based-alignmentmodel, and applying the selected image-alignment model to the firstdigital image and the second digital image to determine the alignmentbetween the first digital image and the second digital image.

The series of acts 900 includes an act 920 of determining a motionvector path for a moving object. In particular, the act 920 can involvedetermining a motion vector path for the moving object based on thefirst digital image, the second digital image, and the alignment.Specifically, the act 920 can include determining, for each pixel in themoving object, a horizontal motion and a vertical motion between thepixel and a corresponding pixel in the second digital image.

The series of acts 900 also includes an act 930 of generating a firstblended image. In particular, the act 930 can involve generating a firstblended digital image by blending pixels from the first digital imageutilizing the motion vector path. Specifically, the act 930 can include,for a first pixel in the first digital image: identifying a set ofpixels from the first digital image along the motion vector path fromthe first pixel; and blending the set of pixels from the first digitalimage along the motion vector path to generate a first blended pixel ofthe first blended digital image. The act 930 can also include averagingpixel values from the set of pixels to generate the first blended pixel.

The series of acts 900 includes an act 940 of generating a virtual longexposure image. In particular, the act 940 can involve generating avirtual long exposure image portraying the moving object in the sequenceof digital images based on the first blended digital image.

The series of acts 900 can also include an additional act of determininga second motion vector path for the moving object based on the seconddigital image and a third digital image in the sequence of digitalimages; and generating a second blended digital image by blending pixelsfrom the second digital image utilizing the second motion vector path.Specifically, this act further includes causing the computing device togenerate the virtual long exposure image portraying the moving object inthe sequence of digital images by combining the first blended digitalimage and the second blended digital image.

Moreover, the virtual long exposure image can comprise a virtuallight-painting long exposure image, which includes a step of generatinga virtual light-painting long exposure image by: comparing a brightnessof a first pixel of the first blended digital image with a brightness ofa corresponding pixel of the second blended digital image; based on thecomparison, selecting a brightest pixel of the first pixel and thecorresponding pixel; and generating a first pixel of the virtuallight-painting long exposure image utilizing the selected brightestpixel.

The virtual long exposure image can comprise a virtual rear-sync flashlong exposure image which includes a step of generating a virtualrear-sync flash long exposure image by: identifying a last digital imagein the sequence of digital images; modifying pixels in the last digitalimage based on a brightness value of the last digital image; andcombining the modified last digital image with the first blended digitalimage to generate the virtual rear-sync flash long exposure image.Specifically, this act can include modifying the first blended digitalimage based on the brightness value of the last digital image; andcombining the modified last digital image with the modified firstblended digital image to generate the virtual rear-sync flash longexposure image.

The term “digital environment,” as used herein, generally refers to anenvironment implemented, for example, as a stand-alone application(e.g., a personal computer or mobile application running on a computingdevice), as an element of an application, as a plug-in for anapplication, as a library function or functions, as a computing device,and/or as a cloud-computing system.

In addition (or in the alternative) to the acts describe above, in someembodiments, the acts 900 include performing a step for generating avirtual long exposure image of the moving object from the alignedplurality of digital images utilizing a motion vector path of the movingobject. For instance, the algorithm and acts described in reference toFIG. 1 can comprise the corresponding acts for performing a step forgenerating a virtual long exposure image of the moving object from thealigned plurality of digital images utilizing a motion vector path ofthe moving object. Similarly, the algorithms and acts described inrelation to FIGS. 2-5 provide additional detail regarding the actsdescribed in FIG. 1 and can further comprise corresponding acts forperforming a step for generating a virtual long exposure image of themoving object from the aligned plurality of digital images utilizing amotion vector path of the moving object.

Embodiments of the present disclosure may comprise or utilize a specialpurpose or general-purpose computer including computer hardware, suchas, for example, one or more processors and system memory, as discussedin greater detail below. Embodiments within the scope of the presentdisclosure also include physical and other computer-readable media forcarrying or storing computer-executable instructions and/or datastructures. In particular, one or more of the processes described hereinmay be implemented at least in part as instructions embodied in anon-transitory computer-readable medium and executable by one or morecomputing devices (e.g., any of the media content access devicesdescribed herein). In general, a processor (e.g., a microprocessor)receives instructions, from a non-transitory computer-readable medium,(e.g., memory), and executes those instructions, thereby performing oneor more processes, including one or more of the processes describedherein.

Computer-readable media can be any available media that can be accessedby a general purpose or special purpose computer system.Computer-readable media that store computer-executable instructions arenon-transitory computer-readable storage media (devices).Computer-readable media that carry computer-executable instructions aretransmission media. Thus, by way of example, and not limitation,embodiments of the disclosure can comprise at least two distinctlydifferent kinds of computer-readable media: non-transitorycomputer-readable storage media (devices) and transmission media.

Non-transitory computer-readable storage media (devices) includes RAM,ROM, EEPROM, CD-ROM, solid state drives (“SSDs”) (e.g., based on RAM),Flash memory, phase-change memory (“PCM”), other types of memory, otheroptical disk storage, magnetic disk storage or other magnetic storagedevices, or any other medium which can be used to store desired programcode means in the form of computer-executable instructions or datastructures and which can be accessed by a general purpose or specialpurpose computer.

A “network” is defined as one or more data links that enable thetransport of electronic data between computer systems and/or modulesand/or other electronic devices. When information is transferred orprovided over a network or another communications connection (eitherhardwired, wireless, or a combination of hardwired or wireless) to acomputer, the computer properly views the connection as a transmissionmedium. Transmissions media can include a network and/or data linkswhich can be used to carry desired program code means in the form ofcomputer-executable instructions or data structures and which can beaccessed by a general purpose or special purpose computer. Combinationsof the above should also be included within the scope ofcomputer-readable media.

Further, upon reaching various computer system components, program codemeans in the form of computer-executable instructions or data structurescan be transferred automatically from transmission media tonon-transitory computer-readable storage media (devices) (or viceversa). For example, computer-executable instructions or data structuresreceived over a network or data link can be buffered in RAM within anetwork interface module (e.g., a “NIC”), and then eventuallytransferred to computer system RAM and/or to less volatile computerstorage media (devices) at a computer system. Thus, it should beunderstood that non-transitory computer-readable storage media (devices)can be included in computer system components that also (or evenprimarily) utilize transmission media.

Computer-executable instructions comprise, for example, instructions anddata which, when executed by a processor, cause a general-purposecomputer, special purpose computer, or special purpose processing deviceto perform a certain function or group of functions. In someembodiments, computer-executable instructions are executed by ageneral-purpose computer to turn the general-purpose computer into aspecial purpose computer implementing elements of the disclosure. Thecomputer-executable instructions may be, for example, binaries,intermediate format instructions such as assembly language, or evensource code. Although the subject matter has been described in languagespecific to structural features and/or methodological acts, it is to beunderstood that the subject matter defined in the appended claims is notnecessarily limited to the described features or acts described above.Rather, the described features and acts are disclosed as example formsof implementing the claims.

Those skilled in the art will appreciate that the disclosure may bepracticed in network computing environments with many types of computersystem configurations, including, personal computers, desktop computers,laptop computers, message processors, hand-held devices, multi-processorsystems, microprocessor-based or programmable consumer electronics,network PCs, minicomputers, mainframe computers, mobile telephones,PDAs, tablets, pagers, routers, switches, and the like. The disclosuremay also be practiced in distributed system environments where local andremote computer systems, which are linked (either by hardwired datalinks, wireless data links, or by a combination of hardwired andwireless data links) through a network, both perform tasks. In adistributed system environment, program modules may be located in bothlocal and remote memory storage devices.

Embodiments of the present disclosure can also be implemented in cloudcomputing environments. As used herein, the term “cloud computing”refers to a model for enabling on-demand network access to a shared poolof configurable computing resources. For example, cloud computing can beemployed in the marketplace to offer ubiquitous and convenient on-demandaccess to the shared pool of configurable computing resources. Theshared pool of configurable computing resources can be rapidlyprovisioned via virtualization and released with low management effortor service provider interaction, and then scaled accordingly.

A cloud-computing model can be composed of various characteristics suchas, for example, on-demand self-service, broad network access, resourcepooling, rapid elasticity, measured service, and so forth. Acloud-computing model can also expose various service models, such as,for example, Software as a Service (“SaaS”), Platform as a Service(“PaaS”), and Infrastructure as a Service (“IaaS”). A cloud-computingmodel can also be deployed using different deployment models such asprivate cloud, community cloud, public cloud, hybrid cloud, and soforth. In addition, as used herein, the term “cloud-computingenvironment” refers to an environment in which cloud computing isemployed.

FIG. 10 illustrates a block diagram of an exemplary computing device1000 that may be configured to perform one or more of the processesdescribed above. One will appreciate that one or more computing devices,such as the computing device 1000 may represent the computing devicesdescribed above (e.g., computing device 800, server device(s) 1002, andclient devices 1004 a-b). In one or more embodiments, the computingdevice 1000 may be a mobile device (e.g., a laptop, a tablet, asmartphone, a mobile telephone, a camera, a tracker, a watch, a wearabledevice, etc.). In some embodiments, the computing device 1000 may be anon-mobile device (e.g., a desktop computer or another type of clientdevice). Further, the computing device 1000 may be a server device thatincludes cloud-based processing and storage capabilities.

As shown in FIG. 10, the computing device 1000 can include one or moreprocessor(s) 1002, memory 1004, a storage device 1006, input/output(“I/O”) interfaces 1008, and a communication interface 1010, which maybe communicatively coupled by way of a communication infrastructure(e.g., bus 1012). While the computing device 1000 is shown in FIG. 10,the components illustrated in FIG. 10 are not intended to be limiting.Additional or alternative components may be used in other embodiments.Furthermore, in certain embodiments, the computing device 1000 includesfewer components than those shown in FIG. 10. Components of thecomputing device 1000 shown in FIG. 10 will now be described inadditional detail.

In particular embodiments, the processor(s) 1002 includes hardware forexecuting instructions, such as those making up a computer program. Asan example, and not by way of limitation, to execute instructions, theprocessor(s) 1002 may retrieve (or fetch) the instructions from aninternal register, an internal cache, memory 1004, or a storage device1006 and decode and execute them.

The computing device 1000 includes memory 1004, which is coupled to theprocessor(s) 1002. The memory 1004 may be used for storing data,metadata, and programs for execution by the processor(s). The memory1004 may include one or more of volatile and non-volatile memories, suchas Random-Access Memory (“RAM”), Read-Only Memory (“ROM”), a solid-statedisk (“SSD”), Flash, Phase Change Memory (“PCM”), or other types of datastorage. The memory 1004 may be internal or distributed memory.

The computing device 1000 includes a storage device 1006 includesstorage for storing data or instructions. As an example, and not by wayof limitation, the storage device 1006 can include a non-transitorystorage medium described above. The storage device 1006 may include ahard disk drive (HDD), flash memory, a Universal Serial Bus (USB) driveor a combination these or other storage devices.

As shown, the computing device 1000 includes one or more I/O interfaces1008, which are provided to allow a user to provide input to (such asuser strokes), receive output from, and otherwise transfer data to andfrom the computing device 1000. These I/O interfaces 1008 may include amouse, keypad or a keyboard, a touch screen, camera, optical scanner,network interface, modem, other known I/O devices or a combination ofsuch I/O interfaces 1008. The touch screen may be activated with astylus or a finger.

The I/O interfaces 1008 may include one or more devices for presentingoutput to a user, including, but not limited to, a graphics engine, adisplay (e.g., a display screen), one or more output drivers (e.g.,display drivers), one or more audio speakers, and one or more audiodrivers. In certain embodiments, I/O interfaces 1008 are configured toprovide graphical data to a display for presentation to a user. Thegraphical data may be representative of one or more graphical userinterfaces and/or any other graphical content as may serve a particularimplementation.

The computing device 1000 can further include a communication interface1010. The communication interface 1010 can include hardware, software,or both. The communication interface 1010 provides one or moreinterfaces for communication (such as, for example, packet-basedcommunication) between the computing device and one or more othercomputing devices or one or more networks. As an example, and not by wayof limitation, communication interface 1010 may include a networkinterface controller (NIC) or network adapter for communicating with anEthernet or other wire-based network or a wireless NIC (WNIC) orwireless adapter for communicating with a wireless network, such as aWI-FI. The computing device 1000 can further include a bus 1012. The bus1012 can include hardware, software, or both that connects components ofcomputing device 1000 to each other.

In the foregoing specification, the invention has been described withreference to specific exemplary embodiments thereof. Various embodimentsand aspects of the invention(s) are described with reference to detailsdiscussed herein, and the accompanying drawings illustrate the variousembodiments. The description above and drawings are illustrative of theinvention and are not to be construed as limiting the invention.Numerous specific details are described to provide a thoroughunderstanding of various embodiments of the present invention.

The present invention may be embodied in other specific forms withoutdeparting from its spirit or essential characteristics. The describedembodiments are to be considered in all respects only as illustrativeand not restrictive. For example, the methods described herein may beperformed with less or more steps/acts or the steps/acts may beperformed in differing orders. Additionally, the steps/acts describedherein may be repeated or performed in parallel to one another or inparallel to different instances of the same or similar steps/acts. Thescope of the invention is, therefore, indicated by the appended claimsrather than by the foregoing description. All changes that come withinthe meaning and range of equivalency of the claims are to be embracedwithin their scope.

1. A non-transitory computer readable medium storing instructionsthereon that, when executed by at least one processor, cause a computingdevice to: determine an alignment between a first digital image and asecond digital image in a sequence of digital images portraying a movingobject; determine a motion vector path for the moving object based onthe first digital image, the second digital image, and the alignment;generate a first blended digital image by blending pixels from the firstdigital image utilizing the motion vector path by, for a first pixel ofthe first digital image: determining a set of pixels along the motionvector path from the first pixel; and blending the set of pixels alongthe motion vector path to generate a first blended pixel of the firstblended digital image; and generate a virtual long exposure imageportraying the moving object in the sequence of digital images based onthe first blended digital image and additional blended digital images.2. The non-transitory computer readable medium of claim 1, furthercomprising instructions that, when executed by the at least oneprocessor, cause the computing device to determine the alignment betweenthe first digital image and the second digital image by: based on afeature-point-deficiency metric, select an image-alignment model from apixel-adjusted-gyroscope-alignment model and a feature-based-alignmentmodel; and apply the selected image-alignment model to the first digitalimage and the second digital image to determine the alignment betweenthe first digital image and the second digital image.
 3. Thenon-transitory computer readable medium of claim 1, further comprisinginstructions that, when executed by the at least one processor, causethe computing device to determine the motion vector path by determining,for each pixel in the moving object, a horizontal motion and a verticalmotion between the pixel and a corresponding pixel in the second digitalimage.
 4. The non-transitory computer readable medium of claim 1 whereinblending the set of pixels from the first digital image furthercomprises: determining background pixels comprising pixels outside ofthe motion vector path; and blending the set of pixels without blendingthe background pixels.
 5. The non-transitory computer readable medium ofclaim 4 wherein blending the set of pixels from the first digital imagealong the motion vector path comprises averaging pixel values from theset of pixels to generate the first blended pixel.
 6. The non-transitorycomputer readable medium of claim 1 further comprising instructionsthat, when executed by the at least one processor, cause the computingdevice to: determine a second motion vector path for the moving objectbased on the second digital image and a third digital image in thesequence of digital images; and generate a second blended digital imageby blending pixels from the second digital image utilizing the secondmotion vector path.
 7. The non-transitory computer readable medium ofclaim 6, further comprising instructions that, when executed by the atleast one processor, cause the computing device to generate the virtuallong exposure image portraying the moving object in the sequence ofdigital images by combining the first blended digital image and thesecond blended digital image.
 8. (canceled)
 9. (canceled)
 10. (canceled)11. A system operable to transform exposure time of images, the systemcomprising a memory comprising a sequence of digital images portraying amoving object; at least one processor; and a computer readable storagemedium storing instructions that, when executed by the at least oneprocessor, cause the system to: determine an alignment between a firstdigital image and a second digital image in the sequence of digitalimages portraying the moving object; determine a motion vector path forthe moving object based on the first digital image, the second digitalimage, and the alignment; generate a first blended digital image basedon the first digital image and the second digital image by, for a firstpixel of the first digital image: determining a set of pixels along themotion vector path from the first pixel; and blending the set of pixelsalong the motion vector path to generate a first blended pixel of thefirst blended digital image; and generate a virtual long exposure imageportraying the moving object in the sequence of digital images based onthe first blended digital image and additional blended digital images.12. The system of claim 11, further comprising instructions that, whenexecuted by the at least one processor, cause the system to: based on afeature-point-deficiency metric, select an image-alignment model from apixel-adjusted-gyroscope-alignment model and a feature-based-alignmentmodel; and apply the selected image-alignment model to the first digitalimage and the second digital image to determine the alignment betweenthe first digital image and the second digital image.
 13. The system ofclaim 11, further comprising instructions that, when executed by the atleast one processor, cause the system to determine the motion vectorpath by determining, for each pixel in the moving object, a horizontalmotion and a vertical motion between the pixel and a corresponding pixelin the second digital image.
 14. The system of claim 11, furthercomprising instructions that, when executed by the at least oneprocessor, cause the system to: determine a second motion vector pathfor the moving object based on the second digital image and a thirddigital image in the sequence of digital images; and generate a secondblended digital image by blending pixels from the second digital imageutilizing the second motion vector path.
 15. The system of claim 14,further comprising instructions that, when executed by the at least oneprocessor, cause the system to generate the virtual long exposure imageportraying the moving object in the sequence of digital images bycombining the first blended digital image and the second blended digitalimage.
 16. (canceled)
 17. (canceled)
 18. In a digital media environment,for capturing and manipulating digital images, a method of transformingexposure time of images comprising: identifying a plurality of digitalimages portraying a moving object; aligning the plurality of digitalimages; and a step for generating a virtual long exposure image of themoving object from the aligned plurality of digital images utilizing amotion vector path of the moving object.
 19. The method of claim 18,further comprising: based on a feature-point-deficiency metric,selecting an image-alignment model from apixel-adjusted-gyroscope-alignment model and a feature-based-alignmentmodel; and applying the image-alignment model to the plurality ofdigital images.
 20. (canceled)
 21. The non-transitory computer readablemedium of claim 1, wherein determining the set of pixels along themotion vector path from the first pixel further comprises: generatingintermediate images of the moving object from the first digital imagealong the motion vector path between a first position and a secondposition, wherein: the first position comprises a location of the movingobject in the first digital image; and the second position comprises alocation of the moving object in the second digital image; andgenerating a number of intermediate samples of each pixel of the movingobject from each of the intermediate images.
 22. The non-transitorycomputer readable medium of claim 21, further comprising instructionsthat, when executed by the at least one processor, cause the computingdevice to select a number of intermediate samples based on a length ofthe motion vector path.
 23. The non-transitory computer readable mediumof claim 21, further comprising instructions that, when executed by theat least one processor, cause the computing device to select a range ofblended images used to generate the virtual long exposure image based onuser input of exposure settings.
 24. The system of claim 11, whereindetermining the set of pixels along the motion vector path from thefirst pixel further comprises: generating intermediate images of themoving object from the first digital image along the motion vector pathbetween a first position and a second position, wherein: the firstposition comprises a location of the moving object in the first digitalimage; and the second position comprises a location of the moving objectin the second digital image; and generating a number of intermediatesamples of each pixel of the moving object from each of the intermediateimages.
 25. The system of claim 24, further comprising instructionsthat, when executed by the at least one processor, cause the system toselect a number of intermediate samples based on a length of the motionvector path.
 26. The system of claim 24, further comprising instructionsthat, when executed by the at least one processor, cause the system toselect a range of blended images used to generate the virtual longexposure image based on user input of exposure settings.